Multiferroic materials for sensors, transducers and memory devices (review
					article)

Zygmunt SUROWIAK; Dariusz BOCHENEK

Authors

Zygmunt SUROWIAK Silesian University, Faculty of Computer and Materials Science, Department of Materials Science
Dariusz BOCHENEK Silesian University, Faculty of Computer and Materials Science, Department of Materials Science

Abstract

Chemical compositions and basic properties of smart materials (ferroics, biferroics, multiferroics) are introduced in this paper. Single phase and composite ferroelectromagnetics are characterized in detail. Multiferroic ferroelectromagnetics are materials which are both ferromagnetic/ferrimagnetic/antiferromagnetic and ferroelectric/ferrielectric, antiferrolectric in the same phase. As a result they have a spontaneous magnetization which can be switched by an applied magnetic field, a spontaneous polarization which can be switched by an applied electric field, and often there is some coupling between those fields. The physical mechanisms of the coupling process were analyzed. In the case of the ferroelectromagnetics in general the transitions method d electrons, which are essential for magnetism, reduce the tendency for off-center ferroelectric distortion. Such materials have all the potential applications of both their parent ferroelectric and ferromagnetic materials.

Keywords:

smart materials, ferroics, multiferroics, ferroelectromagnetics, ferroelectroelastics, single-phases, composites, phase transition

Online first
2025, Vol 50
	No 1
2024, Vol 49
	No 1	No 2	No 3	No 4
2023, Vol 48
	No 1	No 2	No 3	No 4
2022, Vol 47
	No 1	No 2	No 3	No 4
2021, Vol 46
	No 1	No 2	No 3	No 4
2020, Vol 45
	No 1	No 2	No 3	No 4
2019, Vol 44
	No 1	No 2	No 3	No 4
2018, Vol 43
	No 1	No 2	No 3	No 4
2017, Vol 42
	No 1	No 2	No 3	No 4
2016, Vol 41
	No 1	No 2	No 3	No 4
2015, Vol 40
	No 1	No 2	No 3	No 4
2014, Vol 39
	No 1	No 2	No 3	No 4
2013, Vol 38
	No 1	No 2	No 3	No 4
2012, Vol 37
	No 1	No 2	No 3	No 4
2011, Vol 36
	No 1	No 2	No 3	No 4
2010, Vol 35
	No 1	No 2	No 3	No 4
2009, Vol 34
	No 1	No 2	No 3	No 4
2008, Vol 33
	No 1	No 2	No 3	No 4	No 4(S)
2007, Vol 32
	No 1	No 2	No 3	No 4	No 4(S)
2006, Vol 31
	No 1	No 2	No 3	No 4	No 4(S)
2005, Vol 30
	No 1	No 2	No 3	No 4
2004, Vol 29
	No 1	No 2	No 3	No 4
2003, Vol 28
	No 1	No 2	No 3	No 4
2002, Vol 27
	No 1	No 2	No 3	No 4
2001, Vol 26
	No 1	No 2	No 3	No 4
2000, Vol 25
	No 1	No 2	No 3	No 4
1999, Vol 24
	No 1	No 2	No 3	No 4
1998, Vol 23
	No 1	No 2	No 3	No 4
1997, Vol 22
	No 1	No 2	No 3	No 4
1996, Vol 21
	No 1	No 2	No 3	No 4
1995, Vol 20
	No 1	No 2	No 3	No 4
1994, Vol 19
	No 1	No 2	No 3	No 4
1993, Vol 18
	No 1	No 2	No 3	No 4
1992, Vol 17
	No 1	No 2	No 3	No 4
1991, Vol 16
	No 1	No 2	No 3-4
1990, Vol 15
	No 1-2		No 3-4
1989, Vol 14
	No 1-2		No 3-4
1988, Vol 13
	No 1-2		No 3-4
1987, Vol 12
	No 1	No 2	No 3-4
1986, Vol 11
	No 1	No 2	No 3	No 4
1985, Vol 10
	No 1	No 2	No 3	No 4
1984, Vol 9
	No 1-2		No 3	No 4
1983, Vol 8
	No 1	No 2	No 3	No 4
1982, Vol 7
	No 1	No 2	No 3-4
1981, Vol 6
	No 1	No 2	No 3	No 4
1980, Vol 5
	No 1	No 2	No 3	No 4
1979, Vol 4
	No 1	No 2	No 3	No 4
1978, Vol 3
	No 1	No 2	No 3	No 4
1977, Vol 2
	No 1	No 2	No 3	No 4
1976, Vol 1
	No 1	No 2	No 3	No 4

Multiferroic materials for sensors, transducers and memory devices (review article)

Downloads

Authors

Abstract

Keywords:

cover

ippt-pan

Issue

Pages

Section

License

How to Cite

Principal Contact

Address

Support Contact